Doing it yourself may not get you the most precise lab equipment in the world, but it gets you a hands-on appreciation of the techniques that just can’t be beat. Today’s example of this adage: [Stoppi ...

Atomic Force Microscopy (AFM) is a type of high-resolution scanning probe microscopy that allows for imaging, manipulation, and force measurement. Atomic Force Microscopy was first developed in 1986 ...

Atomic force microscopy is a powerful technique that has been widely used in materials research, nano-imaging, and bioimaging. It is a topographical metrology approach that is commonly utilized in ...

Atomic force microscopy (AFM) has emerged as a pivotal technique in biological research, offering unparalleled spatial resolution and force sensitivity to visualise and quantify the nanoscale ...

Graphene is now the most well-known 2D material. It is comprised of a sheet of covalently bonded carbon atoms arranged in a hexagonal lattice where the thickness has been broken down to a single atom.

Graphene is the most well-known member of the 2D materials family. It consists of a sheet of covalently bonded carbon atoms in a hexagonal lattice with the thickness of a single atom. This unique ...

Invented 30 years ago, the atomic force microscope has been a major driver of nanotechnology, ranging from atomic-scale imaging to its latest applications in manipulating individual molecules, ...

Scientists at the Department of Energy's Oak Ridge National Laboratory have reimagined the capabilities of atomic force microscopy, or AFM, transforming it from a tool for imaging nanoscale features ...

Force spectroscopy relies on the precise measurement of forces acting on a probe as it interacts with a sample. The key principles of force spectroscopy include: AFM-based force spectroscopy is the ...

Scientists succeeded in imaging the photocatalytic function of nanoparticles with unprecedently high resolution, which may provide a new tool for nanotechnology and optical manipulation of tiny ...